Instructor Information: Dr. Daniel J. T. Myles Office: Gilbert Hall 145 Phone: 541-737-6756 E-mail: daniel.myles@oregonstate.edu All course information, updates, and announcements are posted via Canvas at: https://oregonstate.instructure.com/ Office Hours: TBA In accord with university policy email inquiries must be sent from your ONID email address. Prerequisties: CH 331 [C- or better] and one year of general chemistry. Meeting Information: Lecture Days: Lecture Times and Location: First and Last Days of Term: Midterm Exam: Final Exam: Monday, Wednesday, and Friday TBA TBA TBA TBA Resources and Materials: Bruice, P. Y. Organic Chemistry, 7 th Edition, Pearson/Prentice Hall, 2014. Organic Molecular Modeling Kit (any number of acceptable kits will suffice) Bruice, P. Y. Organic Chemistry, Study Guide and Solutions Manual, 7 th Edition, Pearson/Prentice Hall, 2014. Tentative Course Outline: (Chapters below are listed in order of lecture presentation.) Chapter 11 Chapter 12 Chapter 14 Chapter 15 Chapter 8 Chapter 19 Chapter 16 Reactions of Alcohols, Ethers, Epoxides, Amines, and Sulfur-Containing Compounds Organometallic Compounds Infrared Spectroscopy NMR Spectroscopy Aromatic, Antiaromatic, and Nonaromatic Compounds Reactions of Benzene and Substituted Benzenes Carbonyl Compounds I Page 1 of 9
Chapter 17 Chapter 21 Carbonyl Compounds II Carbohydrates Midterm Examination: The midterm exam (on TBA) will be administered outside of class. This exam will contain problems similar to those discussed in lecture, the ones assigned from the Canvas quizzes, and the ones assigned from the course textbook. This exam is 80 minutes long. Because exams are promptly marked and returned to the students, no make-up exams can be administered. A missed exam will receive a score of zero. If the university closes (due to inclement weather or for some other unforeseeable reason), the midterm exam will be rescheduled for the following Thursday evening (Week 6), starting at the same time (1900). Final Examination: The final exam will be administered on TBA. Please be on time. A late student may disturb the other students. The final exam is comprehensive. A missed final exam will receive a score of zero. Exam Supplies: 1. Several number two pencils and a good eraser. 2. Molecular model kit; however, the kit must be unassembled prior to the start of the exam. 3. One 3 x 5 card with handwritten or typed notes on one side for the midterm exam and both sides for the final. You must bring your OSU identification card to the exam and present it to the proctor upon completion of the exam. If you bring notes, papers, or books to the exam, place them in a sealed pack and place the pack at the front of the classroom. All audio devices, including CD/MP3 players and mobile telephones, must be turned off and put away during the exam. Policy on Missed Exams: A make-up midterm exam will not be given during the winter offering of CH 332. Midterm Exam: 100 pts Final Exam: 150 pts Total: 250 pts If a student misses the midterm exam due to illness, the final will count for 250 pts. The following scheme will be used: Final Exam: 250 pts Total: 250 pts Page 2 of 9
A missed final will receive a score of zero, unless an unforeseeable circumstance arises, such as a death in ones family or due to a serious illness. An incomplete may be granted at the discretion of the instructor. The final would need to be taken during the 2017 winter offering of CH 332. Evaluation: Maximum Points Midterm Examination 100 Final Examination 150 (or 250)* Blackboard Quizzes 60 Final Score 310 *If the % grade of your final exam is higher than the % grade of your midterm exam, then your final exam % grade will be used to replace your midterm exam grade (as a %). Course grades are based on your overall score according to the following: Letter Grade Minimum Score Needed out of 310 Corresponding Percentage A 285 92% A 279 90% B+ 273 88% B 254 82% B 248 80% C+ 242 78% C 223 72% C 217 70% D+ 211 68% D 192 62% D 186 60% F less than 186 <60% This course is primarily based on lecture material. The textbook is provided as a learning resource and for practice problems. Students are expected to attend lectures and are responsible for all lecture material missed for any reason. The instructor will not give make-up lectures during office hours. Page 3 of 9
Homework: Homework problems from the textbook can be found in the Lecture Schedule and Homework document under Modules in Canvas. These problems will not be graded or collected; however, they are absolutely essential to your success in the course! Canvas Quizzes: Six quizzes will be given throughout the term. These quizzes are open book and open note. You are encouraged to work with your fellow students to answer the questions. Students cannot ask the instructor or TAs questions about the quizzes while they are live. Questions about a particular quiz can only be asked after the appropriate key has posted to Canvas. Late quiz submissions will not be accepted. Complete the quiz early in the week as to avoid any last minute difficulties (i.e., technical or material comprehension). The quiz schedule is shown below: Quiz Post Mon. at 10 AM Due Fri. at 5 PM 1 TBA TBA 2 TBA TBA 3 TBA TBA 4 TBA TBA 5 TBA TBA 6 TBA TBA Recitations: Recitations are 50-minute meetings that are led by a graduate teaching assistant (TA). Students are scheduled for one recitation per week and must attend the recitation section for which they are scheduled! Recitation sections are intended to provide the students with an opportunity to ask questions about the material and for the TAs to reinforce material covered during regular lectures. Video Lecture Captures: Video recordings of Dr. Myles lectures from a past term will be made available in the Modules folder on Canvas. Please note that comments pertaining to both deadlines and content on exams, might not apply to this current course offering of CH 332. If in doubt, please consult this syllabus for current and accurate information regarding deadlines and general course expectations. Student Resources: Your success in CH 332 is very important to me! You have the following resources to help you with your study: 1. Lecture and Recitation Meetings 2. Academic Success Center (http://success.oregonstate.edu/) 3. Textbook Readings 4. Instructor Office Hours Page 4 of 9
Accommodations for Students with Disabilities: Accommodations are a collaborative effort between students, faculty, and Disability Access Services (DAS). Students with accommodations approved through DAS are responsible for contacting the faculty member in charge of the course prior to or during the first week of the term to discuss accommodations. Students who believe they are eligible for accommodations but have not yet obtained approval through DAS should contact DAS immediately at 737-4098. Academic Dishonesty: You will be expected to conduct yourself in a professional manner. Academic dishonesty such as plagiarism and cheating will not be tolerated. Therefore, students are expected to be honest and ethical in their academic work. Academic dishonesty is defined as an intentional act of deception in one of the following areas: * cheating- use or attempted use of unauthorized materials, information or study aids, * fabrication- falsification or invention of any information, * assisting- helping another commit an act of academic dishonesty, * tampering- altering or interfering with evaluation instruments and documents, or * plagiarism- representing the words or ideas of another person as one's own. For more information about academic integrity and the University's policies and procedures in this area, please refer to the Student Conduct website at: http://oregonstate.edu/admin/stucon/achon.htm Student Learning Outcomes The successful student will be able to do the following: Nomenclature be able to give IUPAC names of alcohols, ethers, epoxides, aldehydes, ketones, carboxylic acids, esters and substituted benzenes ( mono-substituted, di-substituted) Alcohols and ethers given an alcohol substrate in conjunction with HX be able to predict the product(s), including stereochemical outcome of substitution (SN1/SN2), predict and explain the distribution of products and display mechanism via given an alcohol substrate in conjunction with H2SO4 be able to predict the product(s), including stereochemical outcome of elimination (E1/E2), predict and explain the distribution of products and display mechanism via given an alcohol substrate in conjunction with PX3 be able to predict the product(s), including stereochemical outcome of substitution (SN2), predict and explain the distribution of products and display mechanism via curved arrow given an alcohol substrate in conjunction with a sulfonyl chloride be able to predict the product(s), including stereochemical outcome of substitution (SN2), predict and explain the distribution of Page 5 of 9
products and display mechanism via given an alcohol substrate in conjunction with H2CrO4/PCC be able to predict the products and predict and explain the distribution of products given an ether substrate in conjunction with HX be able to predict the product(s), including stereochemical outcome of substitution (SN1/SN2), predict and explain the distribution of products and display mechanism via given the reactants be able to predict the products of epoxide opening, predict and explain the distribution of products and display the mechanism via curved arrow formalism under acidic conditions given the reactants be able to predict the products of epoxide opening, predict and explain the distribution of products and display the mechanism via curved arrow formalism under neutral or basic conditions Organometallic compounds given an acetylide ion/organolithium compound/grignard reagent in conjunction with a compound that possesses OH/NH2/ NHR/SH/C CH/CO2H be able to predict the products and predict and explain the distribution of products and display mechanism via given an acetylide ion/organolithium compound/grignard reagent in conjunction with an epoxide be able to predict the products and predict and explain the distribution of products and display mechanism via Aldehydes and ketones given an aldehyde/ketone substrate in conjunction with a hydride reducing agent be able to predict the products, predict and explain the distribution of products and display mechanism via given an aldehyde/ketone substrate in conjunction with an acetylide ion/organolithium compound/grignard reagent be able to predict the products, predict and explain the distribution of products and display mechanism via given an aldehyde/ketone substrate in conjunction with hydrogen cyanide be able to predict the products, predict and explain the distribution of products and display mechanism via curved arrow given an aldehyde/ketone substrate in conjunction with an amine be able to predict the products, predict and explain the distribution of products and display mechanism via curved arrow given an aldehyde/ketone substrate in conjunction with an alcohol be able to predict the products, predict and explain the distribution of products and display mechanism via curved arrow Page 6 of 9
be able to use acetals/ketals as protecting groups Carbohydrates be able to distinguish between simple carbohydrates and complex carbohydrates, between monosaccharides, disaccharides, oligosaccharides and polysaccharides, between aldoses and ketoses, between trioses, tetroses, pentoses, hexoses, etc, and between D sugars and L sugars be able to name/draw furanoses, pyranoses, furanosides and pyranosides be able to recognize alditols, aldonic acids and aldaric acids given a furanose/pyranose/furanoside/pyranoside in conjunction with sodium borohydride be able to predict the products, predict and explain the distribution of products and display mechanism via given a furanose/pyranose/furanoside/pyranoside in conjunction with bromine be able to predict the products, predict and explain the distribution of products given a furanose/pyranose/furanoside/pyranoside in conjunction with Tollens reagent be able to predict the products, predict and explain the distribution of products given a furanose/pyranose/furanoside/pyranoside be able to predict if it will exhibit mutarotation given a furanose/pyranose/furanoside/pyranoside be able to predict if it is a reducing sugar be able to use the Kiliani-Fischer synthesis as means for lengthening the carbon chain of an aldose be able to use the Wohl degradation as a means for shortening the carbon chain of an aldose be able to deduce the structure of an unknown disaccharide Carboxylic acids, esters and related compounds be able to understand the general structure of carboxylic acids and carboxylic acid derivatives given an acyl halide in conjunction with a nucleophilic reagent be able to predict the products, predict and explain the distribution of products and display mechanism via curved arrow given an ester in conjunction with water be able to predict the hydrolysis products, predict and explain the distribution of products and display mechanism via given an ester in conjunction with alcohol be able to predict the transesterified products, predict and explain the distribution of products and display mechanism via given an ester in conjunction with hydroxide ion be able to predict the saponified products, predict Page 7 of 9
and explain the distribution of products and display mechanism via given a carboxylic acid in conjunction with alcohol be able to predict the Fischer esterified products, predict and explain the distribution of products and display mechanism via curved arrow given a carboxylic acid in conjunction with an amine be able to predict the products, predict and explain the distribution of products and display mechanism via Structure determination be familiar with characteristic infrared (IR) absorption bands be able to understand the intensity of absorption bands in connection with relative bond polarity be able to understand the position of an absorption band as it relates to Hooke s law be able to understand how the position of a particular absorption band is influenced by electron delocalization be able to interpret and recognize the presence or absence of important functional groups provided an IR spectrum be able to understand shielding and deshielding in 1 H nuclear magnetic resonance (NMR) spectroscopy be able to recognize chemically and non-chemically equivalent protons be familiar with proton chemical shifts of common functional groups be able to understand both relative and absolute proton ratios and also signal splitting be able to predict and interpret spectral features be able to elucidate structure based on a given proton NMR spectrum Aromaticity and chemistry of benzene be able to characterize a compound as being aromatic, antiaromatic, or nonaromatic given benzene in conjunction with nitric and sulfuric acid be able to predict the nitrated product, predict and explain the distribution of products and display mechanism via curved arrow given benzene in conjunction with a halogen and an iron-based catalyst be able to predict the halogenated product, predict and explain the distribution of products and display mechanism via Page 8 of 9
given benzene in conjunction with sulfuric acid be able to predict the sulfonated product, predict and explain the distribution of products and display mechanism via given benzene in conjunction with an acyl halide and aluminum trihalide be able to predict the acylated product, predict and explain the distribution of products and display mechanism via given benzene in conjunction with an alkyl halide and aluminum trihalide be able to predict the alkylated product, predict and explain the distribution of products and display mechanism via understand electrophilic aromatic substitution reactions of substituted benzenes effect of substituents on reactivity and orientation understand the ortho-para ratio Page 9 of 9